Computing device system and information managing method for rearrangement of data based on access characteristic related to a task

ABSTRACT

Technique for decision criterion for determining a transfer destination layer in rearrangement processing. A computer configures rearrangement reference information showing whether an access characteristic related to a task executed on a plurality of host computing devices is considered as a decision criterion for transfer destination determination in rearrangement processing of transferring data between actual storage areas of physical storage devices of different response performance. Storage subsystem refers to the rearrangement reference information and, based on an access characteristic of the plurality of computing devices with respect to the actual storage areas assigned to the plurality of computing devices, executes rearrangement processing of transferring data stored in the actual storage areas to different actual storage areas in the physical storage devices of different response performance.

CROSS-REFERENCE TO RELATED PATENT APPLICATIONS

This application is a Continuation of U.S. application Ser. No.13/384,966 (National Stage of PCT/JP2011/072058), filed Jan. 19, 2012,incorporated herein by reference in its entirety.

TECHNICAL FIELD

The present invention relates to a computing device system andinformation managing method. For example, the present invention relatesto a technique of managing layers of a storage volume pool in a storagesystem.

BACKGROUND ART

Recently, a technique called “thin provisioning” (for example, seePatent Literature 1) has been actively used in a storage system. Here,the thin provisioning denotes a technique of assigning a virtual volume(or virtual logical volume) to a host computing device. Also, thevirtual volume denotes a volume to which an actual data storage area ona physical disk (hereinafter referred to as “page”) is assigned from apooled logical volume (hereinafter referred to as “pool volume”) at thetime when the host computing device writes data in the virtual volume.

Also, as disclosed in Patent Literature 2, depending on the I/O volumefrom a host computing device for a page assigned to a virtual volume,the page is operated to be moved from a pool volume storing the page toa different pool volume of different performance and cost (rearrangementprocessing). That is, a storage apparatus records the I/O count for eachpage comprising a virtual volume (hereinafter execution of thisrecording is referred to as “I/O monitoring”) and determines a pagearrangement destination layer (i.e., a pool volume classified byperformance and cost) depending on the I/O count. For example, a page ofa larger I/O count is preferentially arranged in a higher layer (i.e.,pool volume of high performance and high cost).

CITATION LIST Patent Literature

-   Patent Literature 1: JP Patent Publication (Kokai) No. 2003-15915 A-   Patent Literature 2: JP Patent Publication (Kokai) No. 2007-66259 A

SUMMARY OF INVENTION Technical Problem

However, a storage apparatus does not recognize what a task on a hostcomputing device actually issuing I/O's is, and therefore the storageapparatus records all I/O's for each page comprising a virtual volume.Consequently, for example, in a case where the I/O count of tasks notrequiring a high response is temporarily high, the I/O count for a pagegroup storing data of tasks requiring a high response is relativelysmaller than the I/O count for a page group storing data of tasks notrequiring a high response, and, as a result, there is a possibility thatthe page group storing data of tasks requiring a high response isarranged in a lower layer, which degrades the performance.

In view of the above situation, therefore, the present inventionprovides a technique of: suitably configuring decision criteria fordetermining a destination layer in rearrangement processing according toa task type and operating status; and preventing performance degradationcaused by arranging data of tasks requiring a high response in a lowerlayer.

Solution to Problem

To solve the above problem, a computing device system of the presentinvention has at least one storage subsystem (i.e., storage apparatus)and a plurality of computing devices connected to the storage subsystem.Here, the storage subsystem has: a plurality of physical storage devicesof different response performance; a memory storing virtual volumemanagement information associating a pool including actual storage areasof the physical storage devices with at least one virtual logical volumecomprising the pool; and a processor which executes processing ofassigning an actual storage area included in the virtual logical volumeto one of the plurality of computing devices. Further, at least onecomputing device (or management computing device or each host computingdevice) of the plurality of computing devices configures rearrangementreference information showing whether an access characteristic relatedto a task executed on the plurality of computing devices is consideredas a decision criterion for transfer destination determination inrearrangement processing of transferring data between the actual storageareas of the plurality of physical storage devices of different responseperformance. Further, the storage subsystem refers to the rearrangementreference information and, based on an access characteristic of theplurality of computing devices with respect to the actual storage areasassigned to the plurality of computing devices, executes rearrangementprocessing of transferring data stored in the actual storage areas todifferent actual storage areas in the physical storage devices ofdifferent response performance.

A further feature related to the present invention is clarified in thedescription of the present specification and the attached drawings.Also, an aspect of the present invention is realized by components,combinations of the components, the following detailed description andaspects of the attached claims.

The description of the present specification is merely a typical exampleand needs to be understood that it does not limit the claims orapplicable examples of the present invention in any meanings.

Advantageous Effects of Invention

According to an embodiment of the present invention, by controllingwhether it is a rearrangement processing target or not (ON/OFF of an I/Omonitoring) according to a type and operating status of a task on ahost, it is possible to prevent performance degradation caused byarranging data of tasks requiring a high response in a lower layer.Further, the user can easily decide which task is set as a rearrangementprocessing target (i.e. to which task's I/O monitoring the ON/OFFcontrol is applied).

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a schematic view of a computing device system (storage system)according to an embodiment of the present invention.

FIG. 2 is a view showing a configuration example of a hardware system ofa host computing device and management server according to the examplesof the present invention.

FIG. 3 is a view showing a hardware system configuration example of astorage apparatus according to the embodiment of the present invention.

FIG. 4 is a view showing a software system configuration example of thecomputing device system according to the embodiment of the presentinvention.

FIG. 5 is a view showing a software system configuration example of thestorage apparatus according to the embodiment of the present invention.

FIG. 6 is a conceptual view showing a relationship example between alogical volume and physical disks according to the embodiment of thepresent invention.

FIG. 7 is a view showing a configuration example of a logical volumemanagement table according to the embodiment of the present invention.

FIG. 8 is a conceptual view showing a relationship example between avirtual volume and the logical volume according to the embodiment of thepresent invention.

FIG. 9 is a view showing a configuration example of a virtual volumemanagement table according to the embodiment of the present invention.

FIG. 10 is a view showing configuration example of a volume poolmanagement table according to the embodiment of the present invention.

FIG. 11 is a view showing a configuration example of a pool layermanagement table according to the embodiment of the present invention.

FIG. 12 is a view showing a configuration example of an unused areamanagement table according to the embodiment of the present invention.

FIG. 13 is a view showing a configuration example of a virtual volumeI/O monitoring ON/OFF management table according to Embodiment 1 of thepresent invention.

FIG. 14 is a flowchart for explaining I/O monitoring processingaccording to Embodiment 1 of the present invention.

FIG. 15 is a flowchart for explaining page layer rearrangementprocessing according to the embodiment of the present invention.

FIG. 16 is a view showing a configuration example of a rearrangementpage management table according to the embodiment of the presentinvention.

FIG. 17 is a view showing a configuration example of a host volumemanagement table according to the embodiment of the present invention.

FIG. 18 is a view showing a configuration example of an I/O monitoringnecessity/unnecessity management table according to the embodiment ofthe present invention.

FIG. 19 is a flowchart for explaining I/O monitoring ON/OFF controlprocessing according to Embodiment 1 of the present invention.

FIG. 20 is a view showing a configuration example of task operationinformation according to the embodiment of the present invention.

FIG. 21 is a view showing a configuration example of an informationdisplay screen for I/O monitoring ON/OFF decision according to theembodiment of the present invention.

FIG. 22 is a view showing a configuration example of a rearrangementcapacity management table according to the embodiment of the presentinvention.

FIG. 23 is a view showing a configuration example of a task operationinformation management table according to the embodiment of the presentinvention.

FIG. 24 is a flowchart for explaining I/O monitoring OFF recommendationdisplay processing according to the embodiment of the present invention.

FIG. 25 is a view showing a configuration example of an I/O monitoringOFF candidate management table per task type according to the embodimentof the present invention.

FIG. 26 is a flowchart for explaining I/O monitoring controlconfiguration recommendation display processing according to theembodiment of the present invention.

FIG. 27 is a view showing a configuration example of a page I/Omonitoring ON/OFF management table according to Embodiment 2 of thepresent invention.

FIG. 28 is a flowchart for explaining I/O monitoring processingaccording to Embodiment 2 of the present invention.

FIG. 29 is a flowchart for explaining I/O monitoring ON/OFF controlprocessing according to Embodiment 2 of the present invention.

FIG. 30 is a flowchart for explaining I/O monitoring ON/OFF controlprocessing according to Embodiment 3 of the present invention.

FIG. 31 is a flowchart for explaining I/O monitoring ON/OFF controlprocessing according to Embodiment 4 of the present invention.

FIG. 32 is a view showing a configuration example of an I/O monitoringcontrol configuration recommendation display screen according to theembodiment of the present invention.

DESCRIPTION OF EMBODIMENTS

Embodiments of the present invention will be explained below withreference to the attached drawings. In the attached drawings, componentsof the same function may be shown by the same number. It should be notedthat, although the attached drawings show detailed embodiments andimplementation examples according to the principle of the presentinvention, these are used to understand the present invention and arenot used to interpret the present invention in a limited way.

Although the present embodiments contain sufficient description to anextent that those skilled in the art can implement the presentinvention, it is essential to understand that other implementations andmodes are possible and it is possible to change the configuration andstructure or replace various components without deviating the scope andspirit of the technical idea of the present invention. Therefore, thefollowing description should not be interpreted in a limited way.

Further, as described below, embodiments of the present invention may beimplemented by software operating on a general-purpose computer,dedicated hardware or a combination of software and hardware.

It should be noted that, although each piece of the information of thepresent invention will be explained below in a “table” format, theseitems of the information need not be necessarily represented by a datastructure in a table format and may be represented by a list, DB, queueor other data structures. Therefore, to show that the information doesnot depend on a data structure, “table,” “list,” “DB” and “queue” may besimply referred to as “information.”

Also, upon explaining the content of each piece of the infatuation, itis possible to use expression of “identification information,”“identifier,” “name,” “appellation” and “ID” and replace these with eachother.

In the following, although each processing in the embodiments of thepresent invention will be explained using a “program” as the subject(i.e., operation subject), determined processing is carried out using amemory and communication port (i.e., communication control apparatus) byexecuting the program in a processor, and therefore the processor may beused as the subject in the explanation. Also, disclosed processing usinga program as the subject may be processing executed by a computingdevice or information processing apparatus such as a management server.Part of or all of the programs may be executed in hardware ormodularized. Various programs may be installed in each computing deviceby a program distribution server or storage medium.

Each embodiment of the present invention provides a technique ofcontrolling ON/OFF of an I/O monitoring according to a task type andoperating status and then preventing performance degradation caused byarranging data of tasks requiring a high response in a lower layer.Also, each embodiment presents effective information to the user todecide in which task the I/O monitoring ON/OFF control is required.

(1) EMBODIMENT 1

Embodiment 1 of the present invention will be explained based on FIGS. 1to 26 and 32.

<Computing Device System and Configuration>

FIG. 1 is a block diagram showing the entire outline of a computingdevice system (or referred to as “storage system” or “IT system”)according to the embodiment of the present invention.

A computing device system 10 has at least one host computing device (orsimply referred to as “host”) 100, at least one management server (orsimply referred to as “management computing device”) 200 and at leastone storage apparatus (or referred to as “storage subsystem”) 400, wherethese components are connected to each other via a LAN 301. Also, thestorage apparatus 400 and the host computing device 100 are connected toeach other via a SAN 300. It should be noted that a plurality of hostcomputing devices may be provided, and, in this case, they may beconnected to each other via a data transfer LAN in addition to the LAN301.

<Internal Configuration of Host Computing Device>

FIG. 2A is a view showing an internal configuration of the hostcomputing device 100. The host computing device 100 has at least one CPU110, at least one memory 111, at least one SAN adapter 112, at least oneLAN adapter 113 and at least one storage device 114, where they areconnected to each other via an internal bus 115.

The host computing device 100 is connected to the storage apparatus 400via the SAN adapter 112. Also, the host computing device 100 isconnected to the management server 200 via the LAN adapter 113. Itshould be noted that the storage device 114 needs not be necessarilyprovided. In a case where the storage device 114 is not provided, avolume in the storage device 400 may be used as a software memory area.

<Internal Configuration of Management Server>

FIG. 2B is a view showing an internal configuration of the managementserver 200. The internal configuration of the management server 200 issimilar to that of the host computing device 100 but does notnecessarily have a SAN adapter.

The management server 200 is connected to the storage apparatus 400 andthe host computing device 100 via a LAN adapter 212.

<Internal Configuration of Storage Apparatus>

FIG. 3 is a view showing an internal configuration of the storageapparatus 400. The storage apparatus 400 has at least one controller 410and at least one physical disk 411.

The controller 410 has at least one CPU 412, at least one memory 413, atleast one NVRAM 414, at least one cache memory 415, at least one backendinterfaces 416 and 417, at least one LAN adapter 418 and at least oneSAN adapter 419, where these components are connected to each other viaan internal bus 420.

The controller 410 is connected to the physical disk 411 via the backendinterfaces 416 and the 417. Also, the storage apparatus 400 is connectedto the management server 200 via the LAN adapter 418. Also, the storageapparatus 400 is connected to the host computing device 100 via the SANadapter 419. Also, the physical disk 411 may comprise multiple kinds ofdisks such as an SAS (Serial Attached SCSI (Small Computer SystemInterface)) disk, an SATA (Serial Advanced Technology Attachment) diskand an SSD (Solid State Drive).

<Software Configuration of Computing Device System>

FIG. 4 is a block diagram showing the outline of a softwareconfiguration of the computing device system 10 according to the presentembodiment. On the host computing device 100, at least one task 500 bycertain application and at least one OS (Operating System) 501 areoperated. This software is stored in the storage device 114 or thestorage apparatus 400, loaded into the memory 110 and executed using theCPU 110.

Also, on the management server 200, management software 600 is operated.The management software 600 is loaded into a memory 211 and executedusing a CPU 210.

Further, on the storage apparatus 400, there is at least one volume pool700 and at least one virtual volume 701 to be created from the volumepool 700 (described later). The virtual volume 701 is assigned to thehost computing device 100 via the SAN 300. It should be noted that thepresent system configuration may include a logical volume (i.e., actualvolume, which is described later) together with the virtual volume 701.

The OS 501 manages and executes the multiple tasks 500 and recognizesand manages the virtual volume 701 and the logical volume 702.

The management software 600 obtains configuration information from thehost computing device 100 and the storage system 400 and stores it amanagement table. The management software 600 will be described later indetail.

<Software Configuration of Storage Apparatus>

FIG. 5 is a view showing the outline of a software configuration in thestorage apparatus 400. On the storage apparatus 400, a storage agent703, a virtual volume manager 704 and a logical volume manager 705 areoperated. These are stored in the physical disk 411 or the NVRAM 414,loaded into the memory 413 and executed using the CPU 412.

The logical volume manager 705 denotes software for creating at leastone logical volume 702 from the physical disk 411 and managing mappingbetween the logical volume 702 and the physical disk 411.

The virtual volume manager 704 denotes software for creating at leastone virtual volume 701 from the logical volume 702 registered in thevolume pool 700 and managing mapping between the virtual volume 701 andthe logical volume 702.

The virtual volume manager 704 denotes software for assigning, when datais written in the virtual volume 701, an unused area from the logicalvolume 702 to a place in which the data is written in the virtual volume701.

<Relationship Between Logical Volume and Physical Disk>

FIG. 6 is a schematic view showing a relationship between the logicalvolume 702 and the physical disk 411. In the example of FIG. 6, thelogical volume 702 is supposed to comprise four physical disks 800, 801,802 and 803. The areas labeled with “1-1,” “1-2,” “1-3,” and so on, inthe physical disks, denote areas divided in predetermined sizes and arecalled “stripes.” Also, the areas labeled “P1,” “P2,” and so on, denoteareas storing parity information of corresponding strips and are called“parity stripes.”

A volume management table is held in the storage apparatus 400 such thatthe logical volume manager 705 manages the mapping relationship betweenthe logical volume 702 and the physical disk 411. The volume managementtable will be described later in detail.

<Volume Management Table>

FIG. 7 is a view showing a configuration example of the volumemanagement table 900 held in the storage apparatus 400. The volumemanagement table comprises a logical volume ID sequence 900, a disksequence 901, a RAID level sequence 902, a stripe size sequence 903 anda disk type sequence 904.

In the logical volume sequence ID 900, the logical volume manager 705 isassigned to each volume and identifiers (i.e., identificationinformation) to specify/identify respective volumes are registered.

In the disk sequence 901, identifiers (i.e., identification information)to specify/identify the physical disks comprising the logical volume areregistered.

In the RAID level sequence 902, RAID levels used in the logical volumeconfigurations are registered.

In the stripe size sequence, stripe sizes used in the logical volumeconfigurations are registered.

In the disk type sequence 904, types of physical disks comprising thelogical volume are registered.

<Relationship Between Virtual Volume and Logical Volume>

FIG. 8 is a conceptual view showing a relationship between the virtualvolume 701 and the logical volume 702. In many cases, an area assignmentto a virtual volume does not mean to assign a physical disk directlythereto but means to comprise a logical volume as shown in FIG. 8 andthen assign a partial area of the virtual volume thereto.

Also, the virtual volume manager 704 (in FIG. 5) manages a relationshipbetween the virtual volume 701 and the logical volume 702 included inthe volume pool 700, and a layer and use status of the logical volume702 in the volume pool. Therefore, a virtual volume management table1100, a volume pool management table 1200, a pool layer management table1300 and an unused area management table 1400 are held in the storageapparatus 400. It should be noted that the virtual volume managementtable 1100, the volume pool management table 1200, the pool layermanagement table 1300 and the unused area management table 1400 will bedescribed later in detail.

<Configuration Example of Virtual Volume Management Table>

FIG. 9 is a view showing a configuration example of the virtual volumemanagement table 1100 held in the storage apparatus 400. The virtualvolume management table 1100 comprises a virtual volume ID sequence1101, a start LBA sequence 1102, an end LBA sequence 1103, a pool IDsequence 1104 and a page ID sequence 1105.

The virtual volume ID sequence 1101 registers identifiers (i.e.,identification information) which are attached to virtual volumes andspecify/identify them.

The start LBA sequence 1102 registers a start LBA's of areas in virtualvolumes. The end LBA sequence 1103 registers an end LBA's of the areasin the virtual volumes.

The pool ID sequence 1104 registers identifiers (i.e., identificationinformation) to specify/identify a volume pool that assigns areas to avirtual volume.

The page ID sequence 1105 registers identifiers (i.e., identificationinformation) to specify/identify pages (described later) correspondingto areas (specified by the start LBA's and end LBA's) of a virtualvolume.

<Volume Pool Management Table>

FIG. 10 is a view showing a configuration example of the volume poolmanagement table 1200 held in the storage apparatus 400.

The volume pool management table 1200 comprises a pool ID sequence 1201,a page ID sequence 1202, a logical volume ID sequence 1203, a start LBAsequence 1204, an end LBA sequence 1205 and a storage I/O count sequence1206.

The pool ID sequence 1201 registers identifiers (i.e., identificationinformation) which are attached to volume pools and specify/identifythem.

The page ID sequence 1202 registers identifiers (i.e., identificationinformation) which are attached to pages and specify/identify them. Itshould be noted that the page is a unit of area assigned from the volumepool 700 to the virtual volume 701. Each page is assigned to any of thelogical volume.

The logical volume ID sequence 1203 registers identifiers (i.e.,identification information) to specify/identify logical volumes in pageassignment destination.

The start LBA sequence 1204 registers a start LBA's of pages in logicalvolumes. Also, the end LBA sequence 1205 registers an end LBA's of thepages in the logical volumes. It is possible to know the page size ofeach page by the start LBA's and end LBA's. Generally, a page size isfixed, but, by appropriately configuring start and end LBAs', it ispossible to register pages of different sizes.

The storage I/O count sequence 1206 records the I/O count issued to eachpage. In FIG. 10, it is configured that the I/O count is not necessaryin a pool 2, and therefore the I/O counts 1206 in the pool 2 are all“0.” The storage I/O count 1206 will be described later in detail.

<Pool Layer Management Table>

FIG. 11 is a view showing a configuration example of the pool layermanagement table 1300 held in the storage apparatus 400.

The pool layer management table 1300 comprises a pool ID sequence 1301,a layer sequence 1302 and a logical volume ID sequence 1303.

The pool ID sequence 1301 registers identifiers (i.e., identificationinformation) to specify/identify volume pools.

The layer sequence 1302 registers layers configured in volume pools. Itshould be noted that a layer is determined based on a disk type or RAIDlevel of a logical volume but may be defined by the user.

The logical volume ID sequence 1303 registers identifiers (i.e.,identification information) to specify/identify logical volumesbelonging to respective layers.

As seen from FIG. 11, for example, a pool 1 comprises two layers ofTier0 and Tier1, Tier0 comprises logical volumes 1 and 2 and Tier1includes logical volumes 0 and 3.

<Unused Area Management Table>

FIG. 12 is a view showing a configuration example of the unused areamanagement table 1400 held in the storage apparatus 400.

The unused area management table 1400 denotes a table for managingunused areas in logical volumes, and comprises a logical volume IDsequence 1401, a start LBA sequence 1402 and an end LBA sequence 1403.

The logical volume ID sequence 1401 registers identifiers (i.e.,identification information) to specify/identify logical volumesregistered in the volume pool 700.

The start LBA sequence 1402 and the end LBA sequence 1403 register startLBA and end LBA sequences of an unused area 1004 in the logical volume702, respectively.

Normally, although logical volume areas are assigned to logical volumesin order of address and then used, a used volume may be released andthen becomes an unused area. Therefore, as shown in FIG. 12, unusedareas may be discontinuous.

<Virtual Volume I/O Monitoring ON/OFF Management Table>

The virtual volume manager 704 records the I/O count (i.e., storage I/Ocount) issued for pages comprising the virtual volume 701, determines alayer of page arrangement destination regularly based on the recordedstorage I/O count and transfers the pages. In the present specification,to record the storage I/O count is referred to as “I/O monitoring,” andto determine a layer of page arrangement destination and transfer thepage is referred to as “page layer rearrangement (or rearrangementprocessing).”

For I/O monitoring and page layer rearrangement, the virtual volumemanager 704 refers to the above-noted virtual volume management table1100, volume pool management table 1200, pool layer management table1300, unused area management table 1400, in addition to a virtual volumeI/O monitoring ON/OFF management table held in the storage apparatus400.

FIG. 13 is a view showing a configuration example of a virtual volumeI/O monitoring ON/OFF management table 1500.

The virtual volume I/O monitoring ON/OFF management table 1500 comprisesa virtual volume ID sequence 1501 and an I/O monitoring ON/OFF sequence1502.

The virtual volume ID sequence 1501 registers identifiers (i.e.,identification information) to specify/identify virtual volumes.

The I/O monitoring ON/OFF sequence 1502 registers whether the I/O countfor the corresponding virtual volume upon I/O monitoring processing isrecorded (ON) or not (OFF). It should be noted that, regardinginformation of this I/O monitoring ON/OFF 1502, although a default valueis configured as the initial value, the value (ON/OFF) changes accordingto processing in FIG. 19 (described later) as the system operatessequentially.

<I/O Monitoring Processing>

FIG. 14 is a flowchart for explaining I/O monitoring processing carriedout by the virtual volume manager 704. The present processing is startedby issuing an I/O from the host computing device 100 to the virtualvolume 701 in the storage apparatus 400 (step 1600). Each stepexplanation will be described below.

Step 1601: The virtual volume manager 704 refers to the virtual volumeI/O monitoring ON/OFF management table 1500 and checks whether thevirtual volume I/O monitoring of the I/O issue destination is in the“ON” condition. In the case of “ON” (i.e., “Yes” in step 1601), theprocess proceeds to step 1602. In the case of “OFF” (i.e., “No” in step1601), the process ends (step 1603).

Step 1602: The virtual volume manager 704 increments, by one, the numberof the storage I/O count sequence 1206 in a line determined by the pageID of I/O issue destination page and the pool ID of a volume pool in thevolume pool management table 1200.

It should be noted that, in order to obtain the latest trend of thestorage I/O count, although the storage I/O count sequence 1206 is restto “0” at regular time intervals, at this time, the storage I/O countbefore the reset may be held as history. In this case, the volume poolmanagement table 1200 holds time zone information recording the storageI/O count. That is, in this case, the volume management table 1200 is asshown in FIG. 23.

Also, the I/O monitoring ON/OFF may be carried out in WWN units ofidentifiers of the SAN adapter 112 of the host computing device 100instead of virtual volume units. In this case, in step 1601, instead ofthe virtual volume I/O monitoring ON/OFF management table 1500, by usingthe virtual volume I/O monitoring ON/OFF management table 1500 replacingthe virtual volume ID sequence 1501 with a host WWN sequence, it isdetermined by the I/O issue source WWN whether there is an I/O record.That is, the I/O count of the I/O issue source is counted.

<Page Layer Rearrangement Processing>

FIG. 15 is a flowchart for explaining page layer rearrangementprocessing carried out by the virtual volume manager 704. The presentprocessing is carried out for each volume pool, started after the elapseof a certain period of time or started by the user's manual operation(step 1700). Each step explanation will be described below.

Step 1701: The virtual volume manager 704 determines the arrangementdestination layer of each page based on the storage I/O count of eachpage recorded in the storage I/O count sequence 1206 of the volume poolmanagement table 1200.

For example, the arrangement destination layer determination method maybe a method of allocating arrangement destination of higher layers topages of larger storage I/O counts in order or a method of allocatingarrangement destination of lower layers to pages of smaller storage I/Ocounts in order. Also, it is possible to determine the arrangementdestination layer of each page taking into account not only the latestrecord recorded as a storage I/O count in the storage I/O count sequence1206 but also a past storage I/O count history, or it is possible todetermine the arrangement destination layer of each page using not onlythe storage I/O count but also other indices. In the case of taking intoaccount the history, the average value of I/O counts for the pastseveral hours are required. By taking into account the history in thisway, although the I/O count increases instantaneously, it is possiblenot to carry out rearrangement in a case where the I/O count is hardlycounted in other periods (or time zone).

Further, for example, it is equally possible to determine thearrangement destination layer taking into account only the read countinstead of taking into account the sum value (i.e., storage I/O count)of read/write counts from the host computing device 100. Also, it isequally possible to determine the arrangement destination layer takinginto account indices such as the random access count and the sequentialread count. The I/O count, the random access count, the sequential readcount, and so on, can be collectively referred to as “access property”or “access characteristic.”

It should be noted that even a page of a virtual volume configured to bein the monitoring OFF condition is the rearrangement processing target.Regarding the page, the I/O count is zero, and therefore the page may betransferred to a lower layer.

Step 1702: The virtual volume manager 704 carries out page transfer(i.e., rearrangement) based on the layer arrangement of each pagedetermined in step 1701. In this case, the transfer target is only apage in which the determined layer and the currently-arranged layer aredifferent. It should be noted that the layer in which each page iscurrently arranged can be checked from a combination of the volume poolmanagement table 1200 and the pool layer management table 1300.

The page transfer is formed with following three transaction processingsfor each page. That is, they include: (i) data of a logical volume area(i.e., old area) in which the page is currently arranged is copied to anunused area (i.e., new area) of a logical volume belonging to adetermined layer; (ii) the logical volume ID sequence 1203, start LBAsequence 1204 and end LBA sequence 1205 of the volume pool managementtable 1200 are updated with new area values; and (iii) a rearrangementpage management table (described later in detail) is updated. Afterprocessings (i) to (iii) are applied to all transfer target pages, theprocess ends (step 1703).

<Rearrangement Page Management Table>

FIG. 16 is a view showing a configuration example of a rearrangementpage management table 1800 held in the storage apparatus 400.

The rearrangement page management table 1800 denotes a table of holdingtransfer history information of pages transferred to layers in the pagelayer rearrangement processing, and comprises a pool ID sequence 1801, apage ID sequence 1802, a transfer original layer 1803 and a transferdestination layer 1804.

The pool ID sequence registers identifiers (i.e., identificationinformation) to specify/identify volume pools.

The page ID sequence registers identifiers (i.e., identificationinformation) to specify/identify pages transferred to layers in the pagelayer rearrangement processing.

The transfer original layer sequence 1803 and the transfer destinationlayer sequence 1804 record page arrangement destination layersbefore/after the page layer rearrangement processing, respectively. Thetransfer destination layer 1804 becomes the transfer original layer 1803at the time of the next rearrangement processing.

It should be noted that the rearrangement page management table 1800 mayhold not only the record of page layer rearrangement processing that iscarried out immediately previously but also a history of past page layerrearrangement processing. In this case, the rearrangement pagemanagement table 1800 holds the time at which the page layerrearrangement processing was carried out. Also, FIG. 16 shows only casesof upgrade or downgrade, but layers may not be changed.

<Host Volume Management Table>

The storage agent 703 attaches storage volume ID's (described later) tothe logical volume 702 and the virtual volume 701 and carries outmanagement. The logical volume 702 and the virtual volume 701 arecollectively referred to as “storage volume.”

FIG. 17 is a view showing a configuration example of a host volumemanagement table 1900 held in the management server 200.

The host volume management table 1900 is created by obtaining, in themanagement software 600, information from the host computing device 100.The host volume management table 1900 comprises a host ID sequence 1901,a host WWN sequence 1902, a host volume ID sequence 1903 and a storagevolume ID sequence 1904.

The host ID sequence 1901 registers identifiers (i.e., identificationinformation) to specify/identify the host computing device 100, wherethe identifiers are attached by the management software 600.

The host WWN sequence 1902 registers identifiers (i.e., identificationinformation) to specify/identify the SAN adapter 112 of the hostcomputing device 100. This information can be used when monitoring theI/O count in WWN units.

The host volume ID sequence 1903 registers identifiers (i.e.,identification information) to specify/identify attached volumesrecognized by the host computing device 100. Hereinafter, volumes to berecognized by the host computing device 100 are referred to as “hostvolumes.”

The storage volume ID sequence 1904 registers identifiers (i.e.,identification information) to specify/identify storage volumescorresponding to host volumes. The storage volume ID denotes informationattached from the storage agent 703 to each storage volume.

It should be noted that, although the storage volume ID denotesinformation attached and held by the storage agent 703, the OS 501obtains the storage volume ID using, for example, an SCSI Inquiry andholds the storage volume ID, in the storage apparatus 400.

For ease of explanation, the storage volume ID in FIG. 17 is expressedby “virtual volume 0,” “logical volume 3,” and so on, but, in manycases, the storage agent 703 actually assigns and manages serial numberswithout distinguishing between the virtual volume and the logicalvolume. In this case, the management software 600 obtains thecorrespondences between the storage volume ID, the virtual volume ID andthe logical volume ID by making an inquiry to the storage agent 703.Thus, it is easily possible to specify the correspondence relationshipsbetween the storage volume ID, the virtual volume ID and the logicalvolume ID. Therefore, instead of describing “a virtual volume IDspecified from a storage volume ID” or “a logical volume ID specifiedfrom a storage volume ID,” it is possible to simply express a virtualvolume ID or a logical volume ID.

Also, in FIG. 17, although host volumes and storage volumes areassociated in a one-to-one correspondence, the one-to-one correspondenceis not essential, and a one-to-many or many-to-one correspondence ispossible.

<I/O Monitoring Necessity/Unnecessity Management Table>

FIG. 18 is a view showing a configuration example of an I/O monitoringnecessity/unnecessity management table 2000 held by the managementserver 200 and referred to by the management software 600.

The I/O monitoring necessity/unnecessity management table 2000 includesa host ID sequence 2001, a task name sequence 2002, a task type sequence2003 and an I/O monitoring necessity/unnecessity sequence 2004.

The host ID sequence 2001 registers identifiers (i.e., identificationinformation) to specify/identify the host computing device 100, wherethe identifiers are attached by the management software 600.

The task name sequence 2002 registers names to distinguish the tasks 500on the OS 501.

The task type sequence 2003 registers general types of the tasks 500.

The I/O monitoring necessity/unnecessity sequence 2004 registers whetherthe I/O count issued by each task needs to be recorded. In thisinformation, for example, the initial values are all set to “necessity”as a default (if the monitoring necessity/unnecessity of a specific taskis known from the beginning, the manager may configure “necessity” or“unnecessity”), and, as the computing device system 10 is operated, theuser (i.e. manager) may make a decision based on the display shown inFIG. 21 (described later) or processing in FIG. 24 or 26 (describedlater) may be carried out to automatically determine the monitoringnecessity/unnecessity as “unnecessity.”

It should be noted that the I/O monitoring necessity/unnecessitymanagement table 2000 may be created by the user by making an input inthe management software 600 or automatically created by the managementsoftware 600 by detecting the tasks 500 operating on the OS 501. The I/Omonitoring necessity/unnecessity management table 2000 is created beforethe I/O monitoring ON/OFF control processing.

Generally, although night summary batch processing is likely not torequire a monitoring, the batch processing is not always completed ontime, and therefore the monitoring may be required. For example, inbatch processing, in a case where the access count for volumes is largeand the end estimation time may be delayed, it is inconvenient if pagesare still arranged in layers of slow access speed. In this case, it isefficient to make a monitoring to allow rearrangement processing. Inthis way, there is a case where tasks not requiring an I/O monitoringare not necessarily clear on the surface, and therefore the processingof the present invention is very effective.

<I/O Monitoring ON/OFF Control Processing>

FIG. 19 is a flowchart for explaining I/O monitoring ON/OFF controlprocessing (example) carried out by the management software 600 in themanagement server 200. The present processing is regularly executedevery host (step 2100). Here, the phrase “regularly executed” meansperiodic execution, the startup of each task, execution on timeconfigured by the user, and so on. That is, it means not only executionat regular intervals but also execution at arbitrarily timing. It shouldbe noted that it may control not only the storage I/O count but also themonitoring ON/OFF of other indices. For example, instead of controllingthe monitoring ON/OFF of the sum value (i.e. storage I/O count) ofread/write counts from the host computing device 100, the monitoringON/OFF of only the read count is controlled. Also, the monitoring ON/OFFof indices such as the random access count and the sequential read countis possible. That is, in the present embodiment, it is possible tocontrol the monitoring ON/OFF of the access property or accesscharacteristic. Regarding I/O monitoring ON/OFF control, each stepexplanation will be described below.

Step 2101: The management software 600 communicates with each hostcomputing device 100 and obtains task operation information 2200 (seeFIG. 20) of each host computing device 100 from the OS 501 on the hostcomputing device 100.

Step 2102: Regarding the obtained task operation information, themanagement software 600 decides whether there is at least one task inwhich an operation status 2202 is ON and the value of the I/O monitoringnecessity/unnecessity sequence 2004 is “unnecessity” in the I/Omonitoring necessity/unnecessity management table 2000. This means thatan I/O monitoring is “OFF” for a virtual volume in which a task notrequiring an I/O-monitoring operates. It should be noted that, as theconditions of “monitoring OFF,” a condition of “a host I/O issue amount2203 equal to or greater than a threshold” is possible, instead of acondition that “the operation status 2202 is ON.” Also, although “themanagement software 600 decides whether there is at least one task,”this can be replaced with description “the management software 600decides whether there is a task equal to or greater than a threshold(e.g., there are three tasks of “unnecessity”).” Alternatively,“monitoring OFF” may be carried out only when “unnecessity” is appliedto all tasks. If a decision result is “yes” in step 2102, the processproceeds to step 2103, and, if the decision result is “no,” the processproceeds to step 2104.

Step 2103: The management software 600 controls the I/O monitoring ofthe virtual volume assigned to the host computing device 100 to “OFF.”To be more specific, first, the management software 600 specifies thevirtual volume ID of a virtual volume assigned to the host computingdevice 100 from the host volume management table 1900 (in FIG. 17) andtransmits the virtual volume ID and an I/O monitoring OFF instruction tothe storage apparatus 400. Then, the storage apparatus 400 havingreceived this OFF instruction applies “OFF” to the value of the I/Omonitoring ON/OFF sequence 1502 of the corresponding virtual volume IDin the virtual volume I/O monitoring ON/OFF management table 1500 (inFIG. 13).

Step 2104: The management software 600 applies “ON” to the I/Omonitoring 1502 of the virtual volume assigned to the host computingdevice 100. To be more specific, first, the management software 600specifies the virtual volume ID of a virtual volume assigned to the hostcomputing device 100 from the host volume management table 1900 andtransmits an I/O monitoring ON instruction including the virtual volumeID to the storage apparatus 400. Then, the storage apparatus 400 havingreceived this ON instruction applies “ON” to the value of the I/Omonitoring ON/OFF sequence 1502 of the corresponding virtual volume IDin the virtual volume I/O monitoring ON/OFF management table 1500.

<Task Operation Information>

FIG. 20 is a view showing an example of the task operation information2200 per host computing device. The task operation information 2200comprises a task name 2201, the operation status 2202 and the host I/Oissue amount 2203.

The task name 2201 denotes information of specifying the names fordistinguishing the tasks 500 on the OS 501.

The operation status 2202 denotes information representing whether eachtask is operated (“ON”) or not (“OFF”).

The host I/O issue amount 2203 denotes information representing the I/Ocount per time issued by each task on the OS 501.

It should be noted that the task operation information 2200 may includeother information such as the memory use amount.

<I/O Monitoring ON/OFF Decision Information Display Screen (GUI)>

FIG. 21 is a view showing a configuration example of an I/O monitoringON/OFF decision information display screen 2300 displayed by themanagement software 600. The I/O monitoring ON/OFF decision informationdisplay screen 2300 denotes a screen used by the user for deciding towhich task's I/O monitoring “OFF control” is applied upon inputting theI/O monitoring necessity/unnecessity management table 2000. FIG. 21shows a user interface for managing the rearrangement occurrence amountper pool in the virtual volume 701. It should be noted that monitoringthe rearrangement occurrence amount per pool applies to not onlyEmbodiment 1 but also Embodiments 2 to 4.

The I/O monitoring ON/OFF decision information display screen 2300includes three general components. That is, they are an intra-poolrearrangement occurrence amount graph 2301, an intra-host task I/O ratiograph 2306 and an all-hosts layer upgrade page I/O contribution rategraph 2307. It should be noted that, although especially upgrade (i.e.,transfer from a lower layer to a higher layer) attracts attention in theintra-host task I/O ratio graph 2306 and the all-hosts layer upgradepage I/O contribution rate graph 2307 in the following description,similar graphs may be displayed by the calculation described below evenfor layer downgrade (i.e., transfer from a higher layer to a lowerlayer). Also, the calculation described below is just an example, andother calculation methods are possible as long as the user can make asimilar decision to that shown below from the graphs of the intra-poolrearrangement occurrence amount graph 2301, intra-host task I/O ratiograph 2306 and all-hosts layer upgrade page I/O contribution rate graph2307.

(i) Intra-Pool Rearrangement Occurrence Amount Graph 2301

The intra-pool rearrangement occurrence amount graph 2301 displays, forpage layer rearrangement processing of the volume pool 700 in each timezone, the sum capacity (i.e., layer upgrade capacity 2304) of a layerupgrade page group (i.e., at least one page transferred from a lowerlayer to a higher layer) and a breakdown 2302 of the host computingdevice to which the page group is assigned for page layer rearrangementprocessing executed in each time zone. Further, regarding a layerdowngrade page group (i.e., at least one page transferred from a higherlayer to a lower layer), the similar information (i.e., a layerdowngrade capacity 2305 and a breakdown 2303 of the host computingdevice to which the page group is assigned) is displayed. It is possibleto decide upgrade pages or downgrade pages from the rearrangement pagemanagement table 1800 (in FIG. 16). Also, it is possible to know the LBArange of each page from the volume pool management table 1200 (in FIG.10), so that it is possible to calculate the capacity of each page basedon the LBA range. Also, it is possible to determine which page isassigned to which host computing device, by referring to the virtualvolume management table 1100 (in FIG. 9), specifying a virtual volumecorresponding to the page ID, referring to the host volume managementtable (in FIG. 17) and obtaining a host computing device to which thevirtual volume ID is assigned.

The user (manager) can decide from the intra-pool rearrangementoccurrence amount graph 2301 which host computing device 100 is a causeof layer upgrade and layer downgrade. Also, the intra-pool rearrangementoccurrence amount graph 2301 is displayed based on a rearrangementcapacity management table 2400 (see FIG. 22).

(ii) Intra-Host Task I/O Ratio Graph 2306

The intra-host task I/O ratio graph 2306 denotes, for example, a graphdisplayed by selecting a host computing device in a time zone to bechecked (e.g., “upgrade host 3” at 24:00) on the intra-poolrearrangement occurrence graph 2301.

The intra-host task I/O ratio graph 2306 shows a “ratio of the host I/Oissue amounts of tasks 500 in each host computing device 100” in a timezone in which page layer rearrangement processing is carried out.

The user can decide, from the intra-host task I/O ratio graph 2306, oneof the tasks 500 which is a cause of layer upgrade of the page groupcorresponding to each host computing device 100, in page layerrearrangement processing in a certain time zone. As shown in FIG. 21, itis possible to recognize an antiviral A as a cause of upgrade inrearrangement processing of host 3 at 24:00.

In step 1701 of the page layer rearrangement processing, the managementsoftware 600 calculates a host I/O issue amount ratio based on the hostI/O issue amount of each task 500 in a time zone in which the storageI/O count used to determine a page arrangement destination layer isrecorded. For example, in step 1701, in the case of using a past storageI/O count held as a history in addition to the latest storage I/O count,the past storage I/O count is included in the above-noted calculation.However, in many cases, the past storage I/O count is less importantthan the latest storage I/O count as a consideration target of pagerearrangement processing. Therefore, upon execution of step 1701, thevirtual volume manger 704 may multiply the past storage I/O count by acertain constant (i.e., weight coefficient) to make the contributionrate lower than the latest storage I/O count. In such a case, uponcalculating “the host I/O issue amount ratio of each task 500 in eachhost computing device 100,” the management software 600 multiples thehost I/O issue amount of each task in the time zone by the samecoefficients by which the virtual volume manager 704 multiples the paststorage I/O count in step 1701. It should be noted that a calculation of“the host I/O issue amount ratio of each task 500 in each host computingdevice 100” is carried out based on a task operation informationmanagement table 2500 (see FIG. 23).

Here, a calculation example of “the host I/O issue amount ratio used todisplay the intra-host task I/O ratio graph 2306 of host 3 on 24:00”will be simply explained using the task operation information managementtable 2500. For example, in page layer rearrangement processing at24:00, it is assumed that the storage I/O count used to determine a pagearrangement destination layer in step 1701 is recorded between 18:00 and24:00 (it should be noted that the time zone in which the storage I/Ocount is recorded is obtained from the virtual volume manager 704). Themanagement software 600 sums up the host I/O issue amounts between 18:00and 24:00 for the tasks of host 3 in the task operation informationmanagement table 2500 (i.e., OLTP3 and antivirus A). The ratio of thissum value is “the host I/O issue amount ratio used to display theintra-host task I/O ratio graph 2306 of host 3 at 24:00.”

(iii) all-Hosts Layer Upgrade Page I/O Contribution Rate Graph 2307

The all-hosts layer upgrade page I/O contribution rate graph 2307denotes, for example, a graph displayed by selecting host computingdevices in a time zone to be checked (e.g., “upgrade host 3” and“upgrade host 2” at 06:00) on the intra-pool rearrangement occurrenceamount graph 2301.

The all-hosts layer upgrade page I/O contribution rate graph 2307 showsthe “layer upgrade contribution rate of each task 500 in all hostcomputing devices 100” in every time zone in which page layerrearrangement processing is carried out.

The user can decide which task 500 of which host computing device 100 isa cause of layer upgrade in page layer rearrangement processing in acertain time zone, by referring to the all-hosts layer upgrade page I/Ocontribution rate graph 2307. As shown in FIG. 21, it is recognized inthe rearrangement processing at 06:00 that OLTP2 of host 2 is dominantand is therefore a cause of upgrade. Therefore, if processing of OLTP2is important, the I/O monitoring necessity/unnecessity is configured to“necessity,” and, if the processing of OLTP2 is not important, the I/Omonitoring necessity/unnecessity is configured to “unnecessity.” Itshould be noted that, even if “unnecessity” is applied to OLTP3 andantivirus A of a small proportion, it can say that it is not effectiveto prevent performance degradation by preventing low layer arrangement.

It should be noted that “the layer upgrade contribution rate of eachtask 500 in all host computing devices 100” displayed in the all-hostslayer upgrade page I/O contribution rate graph 2307 is calculated by themanagement software 600 from “the host I/O issue amount ratios of tasks500 in each host computing device 100” displayed in the intra-host taskI/O ratio graph 2306 and the “breakdown 2302 of the host computingdevices of the layer upgrade capacity 2304.” That is, “the layer upgradecontribution rate of each task 500 in all host computing devices 100” isobtained by multiplying “the host I/O issue amount ratio of each task500 in each host computing device 100” by the ratio of “the breakdown2302 of the host computing devices of the layer upgrade capacity 2304.”

Here, a calculation example of “the layer upgrade contribution rate ofeach task 500 in all host computing devices 100” will be shown. In acase where the layer upgrade capacity 2304 is 100 GB and is made up of70 GB of host 2 and 30 GB of host 3, the ratio of “the breakdown 2302 ofthe host computing devices of the layer upgrade capacity 2304” is 70% ofhost 2 and 30% of host 3. In a case where “the host I/O issue amountratio of each task 500 in each host computing device 100” is made up of100% of OLTP2 in host 2 and 40% of antivirus A and 60% of OLTP3 in host3, “the layer upgrade contribution rate of each task 500 in all hostcomputing devices 100” is made up of 70% (=70%×100%) of OLTP2, 12%(=30%×40%) of antivirus A and 18% (=30%×60%) of OLTP3.

<Rearrangement Capacity Management Table>

FIG. 22 is a view showing a configuration example of the rearrangementcapacity management table 2400 created by the management software 600and held in the management server 200.

The rearrangement capacity management table 2400 comprises a pool IDsequence 2401, a host ID sequence 2402, a rearrangement time zonesequence 2403, a layer upgrade capacity sequence 2404 and a layerdowngrade capacity sequence 2405.

The pool ID sequence 2401 registers identifiers (i.e., identificationinformation) to specify/identify the volume pool 700.

The host ID sequence 2404 registers identifiers (i.e., identificationinformation) to specify/identify a host computing device to which avirtual volume created from a volume pool specified by the value of thepool ID sequence 2401 is assigned.

The rearrangement time zone sequence 2403 registers information showingtime zones in which page layer rearrangement processing is carried outin the storage apparatus 400.

The layer upgrade capacity sequence 2404 and the layer downgradecapacity sequence 2405 register the sum capacities of page groupstransferred from lower layers to higher layers in page layerrearrangement processing and the sum capacities of page groupstransferred from higher layers to lower layers in page layerrearrangement processing, respectively.

The values of the layer upgrade capacity sequence 2404 and layerdowngrade capacity sequence 2405 are calculated by the managementsoftware from 600 the host volume management table 1900, the virtualvolume management table 1100 obtained from the storage apparatus 400,the volume pool management table 1200 and the rearrangement pagemanagement table 1800. For example, in the case of calculating the“layer upgrade capacities of host1 of pool1,” among page groups of pool1registered in the rearrangement page management table 1800, it isidentified that “the value of the transfer destination layer sequence1804 is higher than that of the transfer original layer sequence 1803”and “a host computing device of the assignment destination of thecorresponding virtual volume is host1.” This identification can becarried out by combining the virtual volume management table 1100 andthe host volume management table 1900. By obtaining the identified pagecapacities from the volume pool management table 1200 and summing upthem, it is possible to calculate the “layer upgrade capacities of host1of pool1.”

<Task Operation Information Management Table>

FIG. 23 is a view showing a configuration example of the task operationinformation management table 2500 held by the management server 200.

The task operation information management table 2500 holds historyinformation of the task operation information 2200 of each hostcomputing device 100 and is generated and updated by regularlyobtaining, in the management software 600, the task operationinformation 2200 from each host computing device 100.

The task operation information management table 2500 comprises a host IDsequence 2501, a task name sequence 2502, an operation status sequence2503, a host I/O issue amount sequence 2504 and an extraction timesequence 2505.

The host ID sequence 2501 registers identifiers (i.e., identificationinformation) to specify/identify the host computing device 100.

Information registered in the task name sequence 2502, the operationstatus sequence 2503 and the host I/O issue amount sequence 2504 is thesame as in the items of the same names in the task operation information2200, and therefore explanation will be omitted.

The extraction time sequence 2505 registers the time at which themanagement software 600 obtains the task operation information 2200.

<I/O Monitoring OFF Recommendation Display Processing (I)>

FIG. 24 is a flowchart for explaining I/O monitoring OFF recommendationdisplay processing (example). In the present processing, the managementsoftware 600 automatically presents the task 500 requiring “I/Omonitoring OFF” to the user. In FIG. 21, the user (or manager) decides atask of “I/O monitoring OFF” based on displayed graphs. Therefore, FIG.24 differs from FIG. 21 in presenting a target task automatically, sothat there is an advantage that the user does not have to make adecision.

The task 500 requiring “I/O monitoring OFF” presented in the presentprocessing causes layer upgrade and generally denotes a task typerequiring “I/O monitoring OFF.” Further, the present processing iscarried out every pool of the rearrangement capacity management table2400 regularly or at the time of user instruction (step 2600). However,page layer rearrangement processing is carried out at least one timebefore step 2600, and data needs to be stored in the rearrangementcapacity management table 2400 and the task operation informationmanagement table 2500. Here, the meaning of the term “regularly” is asdescribed above. Each step explanation will be described below.

Step 2601: The management software 600 refers to the rearrangementcapacity management table 2400 and searches a host computing device 100,in which the value of the layer upgrade capacity sequence 2404 is over apredetermined threshold, and the rearrangement time zone. For example,in the case where the threshold is 20 GB (or more), host1 at20:00-24:00, host2 at 12:00-18:00, host2 at 6:00-12:00 and host3 at24:00-6:00 are detected from the rearrangement capacity management table2400.

Step S2602: The management software 600 calculates “the host I/O issueamount ratio of each task 500 in each host computing device 100” foreach “host computing device 100 and rearrangement time zone” found bythe search in step 2601. It should be noted that the “host I/O issueamount ratio of each task 500 in each host computing device 100” is thesame as that used to display the intra-host task I/O ratio graph 2306.

Step 2603: Using the calculation result of step 2602 (i.e., “the hostI/O issue amount ratio of each task 500 in each host computing device100” with respect to each “host computing device 100 and rearrangementtime zone”), the management software 600 searches for the task 500 inwhich “the task is a task type registered in a task type I/O monitoringOFF candidate management table 2700 (in FIG. 25) as an I/O monitoringOFF candidate” and “the host I/O issue amount ratio of each task 500 ineach host computing device 100 is over a predetermined threshold.”

Step 2604: If there is a task 500 obtained by the search in step 2603,the management software 600 presents it to the user as a task requiring“I/O monitoring OFF.”

It should be noted that FIG. 32 is a view showing a configurationexample of an I/O monitoring control configuration recommendationdisplay screen 3400 presented in step 2604. The I/O monitoring controlconfiguration recommendation display screen 3400 comprises a host name3401, a task name 3402, an I/O monitoring OFF checkbox 3403, anexecution button 3404 and a cancellation button 3405.

In the host name 3401 and the task name 3402, the result obtained by thesearch in step 2603 is displayed.

By checking the I/O monitoring OFF checkbox 3403 and pressing theexecution button 3404 by the user, “I/O monitoring OFF” of the task ispossible. That is, it is possible to change the value of the I/Omonitoring necessity/unnecessity sequence 2004 in the line of the taskin the I/O monitoring necessity/unnecessity management table 2000, to“unnecessity,” or display other information. Further, in the presentstep, it is equally possible to not only present a task requiring “I/Omonitoring OFF” to the user but also allow “I/O monitoring OFF”automatically.

<Task Type I/O Monitoring OFF Candidate Management Table>

FIG. 25 is a view showing a configuration example of the task type I/Omonitoring OFF candidate management table 2700 held by the managementserver 200 and referred to by the management software 600.

The task type I/O monitoring OFF candidate management table 2700comprises a task type sequence 2701 and an I/O monitoring OFF candidatesequence 2702.

The task type sequence 2701 registers general types of tasks carried outon the host computing device 100.

The I/O monitoring OFF candidate sequence 2702 registers whether eachtask type is generally subjected to “I/O monitoring OFF” (yes) or not(no). For example, although an index formulation task generally issuesmany I/O's to form the index, an I/O is issued to data not essentiallyrequiring a high response, and therefore this I/O should not be recorded(“I/O monitoring OFF” is required). It should be noted that the tasktype I/O monitoring OFF candidate management table 2700 may be held withfixed values (i.e. default values) by the management software 600 or maybe adequately input by the user.

<I/O Monitoring OFF Recommendation Display Processing (II)>

FIG. 26 is a flowchart for explaining I/O monitoring OFF recommendationdisplay processing different from that of FIG. 24. By the presentprocessing, the management software 600 presents one of the tasks 500requiring “I/O monitoring OFF” to the user. The task 500 (i.e., task A)requiring “I/O monitoring OFF” presented by the present processingcauses layer upgrade equal to or greater than a predetermined thresholdin a certain page layer rearrangement time zone and causes much layerupgrade of at least one different task 500 (i.e., task group B) in thenext page layer rearrangement time zone. That is, a time zone, in whichrearrangement processing equal to or greater than a predeterminedthreshold is carried out, is detected from two (“two” is not essential)consecutive time zones. This does not denote a time zone in which theoccurrence amount of layer upgrade increases discretely, but means thata time zone, in which layer upgrade constantly occurs in a certaindegree, is used as a processing target. In such the task A, the host I/Oissue amount temporarily increases and a page group used in the task Ais subjected to layer upgrade in page layer rearrangement processing,which may result in page layer downgrade of the task group B. Thepresent processing is carried out every pool of the rearrangementcapacity management table 2400 regularly or at the time of userinstruction (step 2800). The meaning of the term “regularly” is asdescribed above. It should be noted that page processing rearrangementprocessing is carried out at least twice before step 2800, and dataneeds to be stored in the rearrangement capacity management table 2400and the task operation information management table 2500. Each stepexplanation will be described below.

Step 2801: The management software 600 refers to the rearrangementcapacity management table 2400 and searches for rearrangement time zonesof a rearrangement time zone to be focused (which is also referred to as“own rearrangement time zone”), the immediately subsequent rearrangementtime zone and a rearrangement time zone in which the all-hosts sum valueof layer upgrade capacities is over a predetermined threshold. It shouldbe noted that, instead of the phrase “the own rearrangement time zoneand immediately subsequent rearrangement time zone,” the phrase “the ownrearrangement time and one of k subsequent rearrangement time zones” ispossible (where k is an arbitrary natural number). For example, the sumvalue (50 GB) of the layer upgrade capacities of host2 and host3 on24:00-6:00 and the sum value (40 GB) of the layer upgrade capacities ofhost2 and host3 on 6:00-12:00 are both over a predetermined threshold(e.g., 35 GB), and therefore these time zones are detected as targets towhich subsequent processing is applied.

Step 2802: The management software 600 calculates the “layer upgradecontribution rate of each task 500 in all host computing devices 100”with respect to rearrangement time zones obtained in step 2801 and therespective subsequent rearrangement time zones. “The layer upgradecontribution rate of each task 500 in all host computing devices 100” isthe same as information used to display the all-hosts layer upgrade pageI/O contribution rate graph 2307.

Step 2803: The management software 600 obtains one of the tasks 500 inwhich: the contribution rate is over a threshold among the “layerupgrade contribution rates of tasks 500 in all host computing devices100” in an arbitrary rearrangement time zone, which is calculated instep 2802; and the contribution rate is less than the threshold among“the layer upgrade contribution rates of tasks 500 in all host computingdevices 100” in the immediately subsequent rearrangement time zone. Forexample, regarding antivirus A, in a case where the contribution rate isover a threshold in a time zone of 18:00-24:00 but is less than thethreshold in a time zone of 24:00-6:00, this antivirus A is obtained asa target task.

Step 2804: If there is the task 500 obtained by the search in step 2803,the management software 600 presents it to the user as a task requiring“I/O monitoring OFF.” It should be noted that information presented instep 2804 is the same as in the I/O monitoring control configurationrecommendation display screen 3400 shown in the above-noted FIG. 32. Itshould be noted that it is equally possible to not only present a taskrequiring “I/O monitoring OFF” to the user but also allow “I/Omonitoring OFF” automatically.

The I/O monitoring OFF recommendation display processing shown in FIGS.24 and 26 is an example, and there is other I/O monitoring OFFrecommendation display processing. For example, the following task 500may be presented to the user as a task requiring “I/O monitoring OFF.”That is, the task 500 denotes a task which causes much layer upgrade ina certain page layer rearrangement time zone and in which most of thepage group subjected to layer upgrade at that time are not frequentlyaccessed after the layer upgrade. In such the task 500, although thehost I/O issue amount is temporarily increased and much layer upgrade iscaused, access is reduced since then, which results in a highpossibility of causing nonsense layer upgrade. It should be noted thatsuch the task 500 can be specified using the volume management table1100, the rearrangement page management table 1800, the virtual hostvolume management table 1900, the rearrangement capacity managementtable 2400 and the task operation information management table 2500.

(2) EMBODIMENT 2

Next, a computing device system according to Embodiment 2 of the presentinvention will be explained with reference to FIGS. 1 to 12, 15 to 18and 20 to 26 used in Embodiment 1, in addition to FIGS. 27 to 29. Itshould be noted that Embodiment 1 and Embodiment 2 are different in thegranularity of I/O monitoring ON/OFF control. That is, althoughEmbodiment 1 carries out I/O monitoring ON/OFF control in virtual volumeunits, Embodiment 2 carries out I/O monitoring ON/OFF control in pageunits.

The system configuration according to Embodiment 2 is the same as thatexplained in Embodiment 1 using FIGS. 1 to 5. Also, the conceptualviews, management tables and flowcharts shown in FIGS. 6 to 12, 15 to 18and 20 to 26 are applied to the present embodiment. However, inEmbodiment 2, the virtual volume 701 is not used as is as a host volume,and a program (i.e., host volume manager) for using, on the hostcomputing device 100 as a virtual host volume, part or a plurality ofareas on at least one virtual volume 701 may be provided on the hostcomputing device 100 or other computing devices. It should be noted thatthe host volume manager holds mapping information between the virtualhost volume and the part or the plurality of areas. Further, not only aphysical machine but also a virtual machine may be provided as the hostcomputing device 100.

<Page I/O Monitoring ON/OFF Management Table>

FIG. 27 is a view showing a configuration example of a page I/Omonitoring ON/OFF management table 2900. This table is used for I/Omonitoring ON/OFF management in page units and is associated with FIG.13 (i.e., a table for I/O monitoring ON/OFF management in virtual volumeunits) according to Embodiment 1.

The page I/O monitoring ON/OFF management table 2900 comprises a pool IDsequence 2901, a page D sequence 2902 and an I/O monitoring ON/OFFsequence 2903.

The pool ID sequence 2901 registers identifiers (i.e., identificationinformation) to specify/identify the respective volume pools 700.

The page ID sequence 2902 registers identifiers (i.e., identificationinformation) to specify/identify the pages of each volume pool 700.

The I/O monitoring ON/OFF sequence 2903 registers whether the I/O withrespect to the page upon I/O monitoring processing is recorded (ON) ornot (OFF). It should be noted that, similar to the I/O monitoring ON/OFF1502 in FIG. 13, although a default value is configured as the initialvalue in this information, the value (ON/OFF) changes according toprocessing in FIG. 29 as the system operates sequentially.

<I/O Monitoring Processing>

FIG. 28 is a flowchart for explaining I/O monitoring processing(example) carried out by the virtual volume manger 704 according toEmbodiment 2. The present embodiment is started at the time of issuingI/O's from the host computing device 100 to the virtual volume 701 inthe storage apparatus 400 (step 3000).

First, the virtual volume manager 704 refers to the page I/O monitoringON/OFF management table 2900 and checks whether the I/O monitoringON/OFF 2903 of an I/O issue destination page is “ON” (step 3001). Atthis time, if the I/O monitoring ON/OFF 2903 is “OFF,” the process ends(step 3003). If the I/O monitoring ON/OFF 2903 is “ON,” the processproceeds to step 3002.

Then, the virtual volume manager 704 increments, by one, the number ofthe storage I/O count sequence 1206 in a line determined by the page IDof the I/O issue destination page and the pool ID of a volume pool inthe volume pool management table 1200 (step 3002), and the process ends(step 3003).

<I/O Monitoring ON/OFF Control Processing>

FIG. 29 is a flowchart for explaining I/O monitoring ON/OFF controlprocessing (example) carried out by the management software 600. Thepresent processing is regularly executed every host computing device 100(step 3100). Here, the significance of the phrase “regularly” is asdescribed above in Embodiment 1. Each step explanation will bedescribed.

Step 3101: The management software 600 obtains the task operationinformation 2200 (see FIG. 20) from the OS 501 on the host computingdevice 100.

Step 3102: The management software 600 specifies a page group assignedto the host computing device 100. In this processing, first, themanagement software 600 obtains, from the OS 501 on the host computingdevice 100, LBA ranges on the virtual volume 701 used by the hostcomputing device 100. In this case, the OS 501 on the host computingdevice 100 manages the LBA ranges on the virtual volume 701 used by thehost computing device. Also, if the host computing device 100 uses apartial area on the virtual volume 701 as a virtual host volume by thehost volume manager, the management software 600 obtains an LBA rangecorresponding to the area from the host volume manager. Next, themanagement software 600 can specify a page group assigned to the hostcomputing device 100 by checking the obtained LBA range using thevirtual volume management table 1100 (in FIG. 9).

Step 3103: Regarding the task operation information 2200 obtained instep 3101, the management software 600 decides whether there is at leastone task in which “the operation status 2202 is ON” and “the value ofthe I/O monitoring necessity/unnecessity sequence 2004 is “unnecessity”in the I/O monitoring necessity/unnecessity management table 2000. Inthe case of “yes” in the decision result of step 3103, the processproceeds to step 3104, and, in the case of “no” in the decision result,the process proceeds to step 3105. It should be noted that, as thecondition, a condition of “the host I/O issue amount 2203 equal to orgreater than a threshold” is possible, instead of a condition that “theoperation status 2202 is ON.” Also, although “the management software600 decides whether there is at least one task,” this can be replacedwith description “the management software 600 decides whether there is atask equal to or greater than a threshold.” This modification example isthe same as in the case of Embodiment 1.

Step 3104: The management software 600 applies “I/O monitoring OFF” to apage group specified in step 3102. That is, the management software 600transmits an I/O monitoring OFF instruction including a volume poolidentifier and the page ID of the page group to the storage apparatus400. After that, the storage apparatus 400 having received this OFFinstruction applies “OFF” to the value of the I/O monitoring ON/OFFsequence 2903 of the corresponding pool ID and page ID in the page I/Omonitoring ON/OFF management table 2900 (in FIG. 27).

Step 3105: The management software 600 applies “I/O monitoring ON” tothe page group specified in step 3102. That is, the management software600 transmits an I/O monitoring ON instruction including the pool ID ofthe volume pool and the page ID of the page group, to the storageapparatus 400. Then, the storage apparatus 400 having received thisinstruction applies “ON” to the I/O monitoring ON/OFF sequence 2903 ofthe corresponding pool ID and page ID in the page I/O monitoring ON/OFFmanagement table 2900.

(3) EMBODIMENT 3

Next, a computing device system according to Embodiment 3 of the presentinvention will be explained with reference to FIGS. 1 to 18 and 20 to 26used in Embodiment 1 in addition to FIG. 30. It should be noted thatEmbodiment 3 is different from Embodiment 1 in that I/O monitoringON/OFF control processing is not carried out by the management software600 of the management server 200 but is carried out by the OS 501 oneach host computing device 100 or the OS 501 of a representative hostcomputing device. Therefore, the management software 600 plays a role ofpresenting the I/O monitoring ON/OFF decision information display screen2300 (in FIG. 21) to the user.

The system configuration according to the present embodiment is the sameas explained in Embodiment 1 using FIGS. 1 to 5. Also, the conceptualviews, management tables and flowcharts shown in FIGS. 6 to 18 and 20 to26 are applied to the present embodiment. However, in a case where theI/O monitoring ON/OFF decision information display screen 2300 needs notbe presented, the management software 600 is not necessarily required.Also, the management software 600 holds the I/O monitoringnecessity/unnecessity management table 2000 and each host computingdevice 100 holds partial information (such as the task name, task typeand I/O monitoring necessity/unnecessity) of the own host ID. The I/Omonitoring necessity/unnecessity management table 2000 held by themanagement software 600 and the I/O monitoring necessity/unnecessitymanagement table partial information held by each host computing device100 are synchronized. Therefore, in the case of inputting the I/Omonitoring necessity/unnecessity management table 2000 by the user, theinput may be made on the management software 600 or on each hostcomputing device 100.

<I/O Monitoring ON/Off Control Processing>

FIG. 30 is a flowchart showing an example of I/O monitoring ON/OFFcontrol processing. The present processing is regularly executed by theOS 501 on each host computing device 100 (step 3200). Here, thesignificance of the phrase “regularly” is as described above. Each stepexplanation will be described.

Step 3201: The OS 501 on each host computing device 100 refers to thetask operation information 2200 (in FIG. 20) of each host computingdevice (i.e., own host).

Step 3202: Regarding the task operation information 2200, the OS 501 oneach host computing device 100 decides whether there is at least onetask in which “the operation status 2202 is ON” and “the value of theI/O monitoring necessity/unnecessity sequence 2004 is “unnecessity” inthe I/O monitoring necessity/unnecessity management table 2000.” In thecase of “yes” in the decision result of step 3202, the process proceedsto step 3203, and, in the case of “no” in the decision result, theprocess proceeds to step 3204. It should be noted that, as a taskprecondition, a condition of “the host I/O issue amount 2203 equal to orgreater than a threshold” is possible, instead of a condition that “theoperation status is ON.” Also, although “the OS 501 on the hostcomputing device 100 decides whether there is at least one task,” thiscan be replaced with description “the OS 501 on the host computingdevice 100 decides whether there is a task equal to or greater than athreshold.” This modification example is the same as in the case ofEmbodiment 1.

Step 3203: The OS 501 on each host computing device 100 applies “I/Omonitoring OFF” to the volume assigned to each corresponding hostcomputing device (i.e., own host computing device). In this processing,an I/O monitoring OFF instruction including a virtual volume ID isissued to the storage apparatus 400 by, for example, SCSI Inquiry. Then,the storage apparatus 400 having received this OFF instruction applies“OFF” to the value of the I/O monitoring ON/OFF sequence 1502 of thecorresponding virtual volume ID in the virtual volume I/O monitoringON/OFF management table 1500 (in FIG. 13).

Step 3204: The OS 501 on each host computing device 100 applies “I/Omonitoring ON” to the volume assigned to each corresponding hostcomputing device (i.e. own host computing device). In this processing,an I/O monitoring ON instruction including a virtual volume ID is issuedto the storage apparatus 400 by, for example, SCSI Inquiry. Then, thestorage apparatus 400 having received this ON instruction applies “ON”to the value of the I/O monitoring ON/OFF sequence 1502 of thecorresponding virtual volume ID in the virtual volume I/O monitoringON/OFF management table 1500.

(4) EMBODIMENT 4

Next, a computing device system according to Embodiment 4 of the presentinvention will be explained with reference to FIGS. 1 to 12, 15 to 18and 20 to 26 used in Embodiment 1 and FIGS. 27 and 28 used in Embodiment2 in addition to FIG. 31. Embodiment 4 is different from Embodiment 1 inthat “I/O monitoring ON/OFF control processing is not carried out by themanagement software 600 but is carried out by the OS 501 on each hostcomputing device 100” and “I/O monitoring ON/OFF control is carried outin page units.” That is, the difference is a combination of those ofEmbodiment 2 and Embodiment 3. Therefore, the management software 600plays a role of presenting the I/O monitoring ON/OFF decisioninformation display screen 2300 to the user.

The system configuration of the present embodiment is the same as thatexplained using FIGS. 1 to 5 in Embodiment 1. Also, the conceptualviews, management tables and flowcharts shown in FIGS. 6 to 18 and 20 to26 are applied to the present embodiment. However, in a case where theI/O monitoring ON/OFF decision information display screen 2300 needs notbe presented, the management software 600 is not necessarily required.Also, the management software 600 holds the I/O monitoringnecessity/unnecessity management table 2000 and each host computingdevice 100 holds partial information (such as the task name, task typeand I/O monitoring necessity/unnecessity) of the own host ID. Also, theI/O monitoring necessity/unnecessity management table 2000 held by themanagement server 200 and used by the management software 600 and theI/O monitoring necessity/unnecessity management table partialinformation held by each host computing device 100 are synchronized.Therefore, in the case of inputting the I/O monitoringnecessity/unnecessity management table 2000 by the user, the input maybe made on the management software 600 of the management server 200 oron each host computing device 100. Further, the virtual volume 701 isnot used as it is as a host volume, and a program (i.e., host volumemanager) for using, on the host computing device 100 as a virtual hostvolume, part or a plurality of areas on at least one virtual volume 701may be provided on the host computing device 100 or other computingdevices. It should be noted that the host volume manager holds mappinginformation between the virtual host volume and the part or theplurality of areas.

<I/O Monitoring ON/OFF Control Processing>

FIG. 31 is a flowchart for explaining I/O monitoring ON/OFF controlprocessing (example) according to Embodiment 4. The present processingis regularly executed by the OS 501 on each host computing device 100(step 3300). Here, the significance of the phrase “regularly” is asdescribed above. Each step explanation will be described.

Step 3301: The OS 501 on each host computing device 100 refers to thetask operation information 2200 (in FIG. 20) of each corresponding hostcomputing device (i.e., own host computing device).

Step 3302: Regarding the task operation information 2200, the OS 501 oneach host computing device 100 decides whether there is at least onetask in which “the operation status 2202 is ON” and “the value of theI/O monitoring necessity/unnecessity sequence 2004 is “unnecessity” inthe I/O monitoring necessity/unnecessity management table 2000.” In thecase of “yes” in the decision result of step 3302, the process proceedsto step 303, and, in the case of “no” in the decision result, theprocess proceeds to step 3304. It should be noted that, as a taskprecondition, a condition of “the host I/O issue amount 2203 equal to orgreater than a threshold” is possible, instead of a condition that “theoperation status is ON.” Also, although “the OS 501 on the hostcomputing device 100 decides whether there is at least one task,” thiscan be replaced with description “the OS 501 on the host computingdevice 100 decides whether there is a task equal to or greater than athreshold.” This modification example is the same as in the case ofEmbodiment 1.

Step 3303: The OS 501 on each host computing device 100 applies “I/Omonitoring OFF” in at least one area on the virtual volume 701. In thisprocessing, an I/O monitoring OFF instruction including the virtualvolume ID and LBA range is transmitted to the storage apparatus 400 by,for example, SCSI Inquiry. The storage apparatus 400 having receivedthis OFF instruction refers to the virtual volume management table 1100(in FIG. 9), specifies the pool ID and page ID corresponding to theinstructed virtual volume ID and LBA range, and, based on thesespecified pool ID and page ID, applies “OFF” to the value of the I/Omonitoring ON/OFF sequence 2903 in the page I/O monitoring ON/OFFmanagement table 2900 (in FIG. 27). In this case, the OS 501 manages LBAranges on the virtual volume 701 used by each corresponding hostcomputing device (i.e., own host computing device). It should be notedthat, if the host computing device 100 uses a partial area on thevirtual volume 701 as a virtual host volume by the host volume manager,the OS 501 on the host computing device 100 issues an I/O monitoring OFFinstruction related to the virtual host volume to the host volumemanager. The host volume manager receives this instruction andtransmits, by SCSI Inquiry for example, an I/O monitoring OFFinstruction including the virtual volume ID and LBA ranges on thevirtual volume 701 corresponding to the virtual host volume, to thestorage apparatus 400.

Step 3304: The OS 501 on each host computing device 100 applies “I/Omonitoring ON” in at least one area on the virtual volume 701 assignedto each corresponding host computing device (i.e., own host computingdevice). In this processing, an I/O monitoring ON instruction includingthe virtual volume ID and LBA range is transmitted to the storageapparatus 400 by, for example, SCSI Inquiry. The storage apparatus 400having received this ON instruction refers to the virtual volumemanagement table 1100, specifies the pool ID and page ID correspondingto the instructed virtual volume ID and LBA range, and, based on thesespecified pool ID and page ID, applies “ON” to the value of the I/Omonitoring ON/OFF sequence 1502 in the page I/O monitoring ON/OFFmanagement table 2900. In this case, the OS 501 manages LBA ranges onthe virtual volume 701 used by each corresponding host computing device(i.e., own host computing device). It should be noted that, if the hostcomputing device 100 uses a partial area on the virtual volume 701 as avirtual host volume by the host volume manager, the OS 501 on the hostcomputing device 100 issues an I/O monitoring ON instruction related tothe virtual host volume to the host volume manager. The host volumemanager receives this instruction and transmits, by SCSI Inquiry forexample, an I/O monitoring ON instruction including the virtual volumeID and LBA ranges on the virtual volume 701 corresponding to the virtualhost volume, to the storage apparatus 400.

(5) CONCLUSION

In each embodiment of the present invention, a storage apparatus carriesout rearrangement processing based on the access characteristic (e.g.,I/O count) related to tasks executed on a plurality of computing devices(i.e., host computing devices). In this case, a management computingdevice or host computing device monitors the I/O count in virtuallogical volume units, the I/O count in units of pages comprising avirtual volume (i.e., in units of access to an actual storage area of avirtual logical volume) or the I/O count issued by the host computingdevice (i.e., in units of access to a storage subsystem by the hostcomputing device that executes a task), thereby deciding whetherrearrangement processing is carried out. Here, the embodiments configureI/O monitoring ON/OFF management information (see FIGS. 13 and 27) toshow whether I/O monitoring is carried out. Then, the storage apparatusrefers to this I/O monitoring ON/OFF management information and carriesout rearrangement processing based on the I/O count from the monitoredhost computing device. Although embodiments configure information (i.e.,I/O monitoring ON/OFF management information) to show whether I/Omonitoring is carried out, even if the I/O count (i.e., accesscharacteristic) is monitored, the I/O count may not be used forrearrangement processing necessity/unnecessity decision, and thereforeit is possible to simply adopt expression “configure rearrangementreference information showing whether it is considered as a decisioncriterion for transfer destination in rearrangement processing,” insteadof I/O monitoring ON/OFF management information. By this means, apredetermined virtual volume, a page or a host volume need not be usedfor rearrangement processing necessity/unnecessity decision, so that itis possible to prevent unnecessary rearrangement processing.

Also, in each embodiment of the present invention, a managementcomputing device or host computing device generates and outputsinformation (i.e., rearrangement occurrence information including anintra-host task I/O ratio and all-hosts layer upgrade page I/Ocontribution rate) showing the data rearrangement occurrence amount (atleast layer upgrade capacity) per storage area used by tasks executed ina plurality of host computing devices (or the own host computing devicein a case where each host computing device has a management computingdevice function (i.e. in the case of Example 3)) (see FIG. 21). By thismeans, the user (or manager) can determine the I/O monitoringnecessity/unnecessity (i.e., rearrangement processingnecessity/unnecessity) for each task with reference to the outputinformation. Therefore, the user can determine the I/O monitoringnecessity/unnecessity along the execution tendency of each task, so thatit is possible to provide a computing device system (or storage system)that is easily managed by the user.

On the other hand, it may be possible to automatically configure the I/Omonitoring necessity/unnecessity (i.e., rearrangement processingnecessity/unnecessity) or present a task recommended to be “monitoringOFF” to the user. By this means, the user who is not familiar with I/Omonitoring necessity/unnecessity decision can appropriately manage thestorage system. It should be noted that, specifically, a monitoring OFFrecommendation task display can be realized by executing the processingshown in FIGS. 24 and 26.

(ii) The present invention can be realized by a program code of softwarerealizing the functions of embodiments. In this case, a storage mediumrecording the program code is provided to a system or apparatus, and acomputer (or CPU or MPU) of the system or apparatus reads the programcode stored in the storage medium. In this case, the program code itselfread from the storage medium realizes the above-noted functions ofembodiments, and the program code itself and the storage medium storingthe program code form the present invention. Examples of storage mediaused to provide such a program code include a flexible disk, CD-ROM,DVD-ROM, hard disk, optical disk, magnetooptical disk, CD-R, magnetictape, nonvolatile memory card and ROM.

Also, based on the program code instruction, an OS (Operating System)operating on a computer may carry out part or whole of actual processingand realize the functions of above-noted embodiments by the processing.Further, after the program code read from a storage medium is written ina memory on a computer, for example, the computer CPU may carry our partor whole of actual processing based on the program code instruction andrealize the functions of above-noted embodiments by the processing.

Further, by delivering a software program code to realize the functionsof the embodiments via a network, it may be possible to store theprogram code in a storage section such as a hard disk and memory in asystem or apparatus, or store it in a storage medium such as CD-RW andCD-R, and, upon use, allow a computer (or CPU or MPU) of the system orapparatus to read and execute the program code stored in the storagesection or the storage medium.

Finally, it is necessary to understand that the above-described processand techniques are not essentially related to any specific apparatusesbut can be realized by any suitable combinations of components. Further,it is possible to use various types of general-purpose devices accordingto the above-noted teaching. It may be understood that forming adedicated apparatus is effective to execute the steps of theabove-described method. Also, it is possible to form various aspects ofthe invention by suitably combining a plurality of components disclosedin the embodiments. For example, some components may be removed from allcomponents disclosed in the embodiments. Further, some componentsbetween embodiments may be appropriately combined. Although the presentinvention is described in association with specific examples, these arenot provided for limitation in all views but are provided forexplanation. Those skilled in the art can understand that manycombinations of hardware, software and firmware suitable to implementthe present invention are provided. For example, the described softwarecan be implemented by wide-range program or script language such asassembler, C/C++, perl, Shell, PHP and Java (registered trademark).

Further, the above-noted embodiments show control lines and informationlines considered to be required for explanation, and all control linesand information lines on products may not be necessarily shown. Allcomponents may be connected to one another.

In addition, for a person having normal knowledge of the presenttechnical field, other implementations of the present invention areclear from consideration of the disclosed specification and embodimentsof the present invention. The various aspects and/or components of thedescribed embodiments can be used independently or by any combinationsin a computerized storage system having a function of data management.The specification and specific examples are just typical examples, andthe scope and spirit of the present invention are defined in thefollowing claims.

REFERENCE SIGNS LIST

-   100 HOST COMPUTING DEVICE-   200 MANAGEMENT SERVER (MANAGEMENT COMPUTING DEVICE)-   300 SAN-   301 LAN-   400 STORAGE APPARATUS-   700 VOLUME POOL-   701 VIRTUAL VOLUME (VIRTUAL LOGICAL VOLUME)-   800 to 803 PHYSICAL DISK-   900 LOGICAL VOLUME MANAGEMENT TABLE (LOGICAL VOLUME MANAGEMENT    INFORMATION)-   1100 VIRTUAL VOLUME MANAGEMENT TABLE (VIRTUAL VOLUME MANAGEMENT    INFORMATION)-   1200 VOLUME POOL MANAGEMENT TABLE (VOLUME POOL MANAGEMENT    INFORMATION)-   1300 POOL LAYER MANAGEMENT TABLE (POOL LAYER MANAGEMENT INFORMATION)-   1400 UNUSED AREA MANAGEMENT TABLE (UNUSED AREA MANAGEMENT    INFORMATION)-   1500 VIRTUAL VOLUME I/O MONITORING ON/OFF MANAGEMENT TABLE (VIRTUAL    VOLUME I/O MONITORING ON/OFF MANAGEMENT INFORMATION)-   1800 REARRANGEMENT PAGE MANAGEMENT TABLE (REARRANGEMENT PAGE    MANAGEMENT INFORMATION)-   1900 HOST VOLUME MANAGEMENT TABLE (HOST VOLUME MANAGEMENT    INFORMATION)-   2000 I/O MONITORING NECESSITY/UNNECESSITY MANAGEMENT TABLE (I/O    MONITORING NECESSITY/UNNECESSITY MANAGEMENT INFORMATION)-   2200 TASK OPERATION INFORMATION-   2400 REARRANGEMENT CAPACITY MANAGEMENT TABLE (REARRANGEMENT CAPACITY    MANAGEMENT INFORMATION)-   2500 TASK OPERATION INFORMATION MANAGEMENT TABLE (TASK OPERATION    MANAGEMENT INFORMATION)-   2700 TASK TYPE I/O MONITORING OFF CANDIDATE MANAGEMENT TABLE (TASK    TYPE I/O MONITORING OFF CANDIDATE MANAGEMENT INFORMATION)-   2900 PAGE I/O MONITORING ON/OFF MANAGEMENT TABLE (PAGE I/O    MONITORING ON/OFF MANAGEMENT INFORMATION)

1. A computing device system comprising at least one storage subsystemand a plurality of computing devices connected to the at least onestorage subsystem, the at least one storage subsystem comprising: aplurality of physical storage devices of different responseperformances; a memory configured to store virtual logical volumemanagement information associating a pool including actual storage areasof the plurality of physical storage devices with at least one virtuallogical volume comprising the pool; and a processor configured toexecute processing of assigning an actual storage area included in theat least one virtual logical volume to one of the plurality of computingdevices, wherein at least one computing device of the plurality ofcomputing devices is configured to manage rearrangement referenceinformation showing whether a characteristic of accesses counted withrespect to each of a plurality of predetermined units is considered as adecision criterion for transfer destination determination inrearrangement processing of transferring data between actual storageareas of the plurality of physical storage devices of the differentresponse performances, and wherein the processor of the at least onestorage subsystem is configured to refer to the rearrangement referenceinformation and, based on the characteristic of accesses of theplurality of computing devices with respect to the actual storage areasassigned to the plurality of computing devices, to execute rearrangementprocessing of transferring data stored in the actual storage areas todifferent actual storage areas in the plurality of physical storagedevices of the different response performances.
 2. The computing devicesystem according to claim 1, wherein the characteristic of accesses isan access characteristic related to a task executed on the plurality ofcomputing devices, and wherein at least one computing device of theplurality of computing devices is configured to manage rearrangementreference information showing whether the access characteristic relatedto the task executed on the plurality of computing devices is consideredas a decision criterion for transfer destination determination inrearrangement processing of transferring data between the actual storageareas of the physical storage devices of different responseperformances.
 3. The computing device system according to claim 2,wherein the at least one computing device of the plurality of computingdevices is configured to generate and output rearrangement occurrenceinformation showing a rearrangement occurrence amount of data perstorage area used by the task executed on a subset of the plurality ofcomputing devices.
 4. The computing device system according to claim 3,wherein, based on the rearrangement occurrence information, the at leastone computing device is configured to determine rearrangementnecessity/unnecessity information showing a task requiring therearrangement processing, and to manage the rearrangement referenceinformation based on the rearrangement necessity/unnecessityinformation.
 5. The computing device system according to claim 4,wherein the at least one computing device is configured to determine therearrangement necessity/unnecessity information in response to aninstruction input by a user according to an output of the rearrangementoccurrence information.
 6. The computing device system according toclaim 4, wherein the at least one computing device is configured to:hold decision elimination candidate information showing a task that is acandidate to be eliminated from the decision criterion for the transferdestination determination in the rearrangement processing with respectto a plurality of tasks; calculate first rearrangement occurrence ratioinformation showing a ratio of data rearrangement occurrence amounts oftasks for each of the computing devices; specify a task which isincluded in the decision elimination candidate information and in whichthe first rearrangement occurrence ratio information exceeds a firstthreshold; and output the specified task as the rearrangementnecessity/unnecessity information.
 7. The computing device systemaccording to claim 4, wherein the at least one computing device isconfigured to: generate the rearrangement occurrence information over aplurality of time zones in which the rearrangement processing isexecuted; specify at least two consecutive time zones in which a sumvalue of rearrangement occurrence amounts of data related to allcomputing devices executing tasks exceeds a second threshold; calculatesecond rearrangement occurrence ratio information showing a ratio ofrearrangement occurrence amounts of the data related to all computingdevices executing the task, in each of the specified consecutive timezones; specify a task in which the second rearrangement occurrence ratioinformation of one of the at least two specified consecutive time zonesexceeds a third threshold, and the second rearrangement occurrence ratioinformation of another of the at least two specified consecutive timezones is below the third threshold; and output the specified task as therearrangement necessity/unnecessity information.
 8. The computing devicesystem according to claim 2, wherein the plurality of computing devicescomprises a plurality of host computing devices and at least onemanagement computing device, and wherein the at least one computingdevice that is configured to manage the rearrangement referenceinformation is the at least one management computing device.
 9. Thecomputing device system according to claim 2, wherein the plurality ofcomputing devices comprises a plurality of host computing devices and atleast one management computing device, and wherein each of the pluralityof host computing devices is configured to manage the rearrangementreference information related to an own host computing device.
 10. Thecomputing device system according to claim 2, wherein the at least onecomputing device is configured to manage the rearrangement referenceinformation in a unit of the virtual logical volume, in a unit of accessfor the at least one storage subsystem by the computing devicesexecuting the task, or in a unit of access for the actual storage areaof the at least one virtual logical volume.
 11. The computing devicesystem according to claim 3, wherein the at least one computing deviceemploys a data amount rearranged from a first layer to a second layer asthe rearrangement occurrence amount of the data, wherein the first layercomprises a physical storage device having a response performance equalto a predetermined value, and wherein the second layer comprises aphysical storage device having a higher response performance than thatof the first layer.
 12. An information management method for a computingdevice system comprising at least one storage subsystem and a pluralityof computing devices connected to the at least one storage subsystem,the at least one storage subsystem comprising: a plurality of physicalstorage devices of different response performances; a memory configuredto store virtual logical volume management information associating apool including actual storage areas of the plurality of physical storagedevices with at least one virtual logical volume comprising the pool;and a processor configured to execute processing for assigning an actualstorage area included in the at least one virtual logical volume for oneof the plurality of computing devices, the information management methodcomprising: configuring, by at least one computing device of theplurality of computing devices, rearrangement reference informationshowing whether a characteristic of accesses counted with respect toeach of a plurality of predetermined units is considered as a decisioncriterion for transfer destination determination in rearrangementprocessing of transferring data between the actual storage areas of theplurality of physical storage devices of the different responseperformances, referencing, by the processor, the rearrangement referenceinformation, and executing, by the processor, rearrangement processingso as to transfer data stored in the actual storage areas to differentactual storage areas in the plurality of physical storage devices of thedifferent response performances, based on an access characteristic ofthe plurality of computing devices with respect to the actual storageareas assigned to the plurality of computing devices.
 13. Theinformation management method according to claim 12, wherein thecharacteristic of accesses is an access characteristic related to a taskexecuted on the plurality of computing devices, and wherein the methodfurther includes managing, by at least one computing device of theplurality of computing devices, rearrangement reference informationshowing whether the access characteristic related to a task executed onthe plurality of computing devices is considered as a decision criterionfor transfer destination determination in rearrangement processing oftransferring data between the actual storage areas of the plurality ofphysical storage devices of the different response performances.
 14. Theinformation management method according to claim 13, further comprising:generating and outputting, by the at least one computing device of theplurality of computing devices, rearrangement occurrence informationshowing a rearrangement occurrence amount of data per storage area usedby the task executed on a subset of the plurality of computing devices.15. The information management method according to claim 14, furthercomprising: determining, by the at least one computing device,rearrangement necessity/unnecessity information showing a task requiringthe rearrangement processing, based on the rearrangement occurrenceinformation, and managing, by the at least one computing device, therearrangement reference information based on the rearrangementnecessity/unnecessity information.
 16. The information management methodaccording to claim 15, further comprising the at least one computingdevice performing the steps: holding, by the at least one computingdevice, decision elimination candidate information showing a task thatis a candidate to be eliminated from the decision criterion for thetransfer destination determination in the rearrangement processing withrespect to a plurality of tasks, calculating first rearrangementoccurrence ratio information showing a ratio of data rearrangementoccurrence amounts of tasks for each of the computing devices,specifying a task which is included in the decision eliminationcandidate information and in which the first rearrangement occurrenceratio information is over a first threshold, and outputting thespecified task as the rearrangement necessity/unnecessity information.17. The information management method according to claim 15, furthercomprising the at least one computing device performing the steps:generating the rearrangement occurrence information over a plurality oftime zones in which the rearrangement processing is executed; specifyingat least two consecutive time zones in which a sum value ofrearrangement occurrence amounts of the data related to all computingdevices executing tasks exceeds a second threshold; calculating secondrearrangement occurrence ratio information showing a ratio ofrearrangement occurrence amounts of the data related to all computingdevices executing the task, in each of the specified consecutive timezones; specifying a task in which the second rearrangement occurrenceratio information of one of the specified at least two consecutive timezones exceeds a third threshold and in which the second rearrangementoccurrence ratio information of another of the specified at least twoconsecutive time zones is below the third threshold; and outputting thespecified task as the rearrangement necessity/unnecessity information.